Advance in silicon phased-array receiver IC's

2012 IEEE/MTT-S International Microwave Symposium Digest Pub Date : 2012-06-17 DOI:10.1109/MWSYM.2012.6259603

F. V. van Vliet, E. Klumperink, Michiel C. M. Soer, S. K. Garakoui, A. de Boer, A. P. de Hek, W. Heij, B. Nauta

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引用次数: 4

Abstract

Phased-Arrays are increasingly used, and require Silicon implementations to result in affordable multi-beam systems. In this paper, CMOS implementations of two novel analogue beamforming multi-channel receivers will be presented. A narrow-band highly linear system exploiting switches and capacitors in advanced CMOS is presented, implementing a fully passive switched capacitor vector modulator exploiting a zero-IF I/Q mixer: This technique is not applicable to very wideband phased-array receivers. These systems require true-time delay beamforming, which is implemented in the second CMOS implementation. An innovative gm-RC implementation of a true-time delay cell is exploited in a four-channel beamforming receiver with more than 1.5 GHz bandwidth, in a standard 0.13 um CMOS process. Professional phased-arrays can often not live with the dynamic range limitations imposed by these implementations. To that end a SiGe implementation of an integrated receiver was realized targeting a digital beamforming phased-array. Dynamic range and flexibility of use were the main driving factors. Alltogether, these results show large progress with respect to the feasibility of Silicon-based phased-array front-end implementation for commercial as well as professional phased-arrays.

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硅相控阵接收机集成电路的研究进展

相控阵越来越多地使用，并且需要硅实现来实现经济实惠的多波束系统。本文将介绍两种新型模拟波束形成多通道接收机的CMOS实现。提出了一种利用先进CMOS开关和电容的窄带高线性系统，实现了一种利用零中频I/Q混频器的全无源开关电容矢量调制器。这种技术不适用于宽带相控阵接收机。这些系统需要实时延迟波束形成，这在第二个CMOS实现中实现。在标准的0.13 um CMOS工艺中，在带宽超过1.5 GHz的四通道波束成形接收器中开发了一种创新的gm-RC实时延迟单元实现。专业相控阵通常无法适应这些实现所带来的动态范围限制。为此，实现了一种针对数字波束形成相控阵的集成接收机的SiGe实现。动态范围和使用灵活性是主要驱动因素。总之，这些结果显示了硅基相控阵前端在商业和专业相控阵应用方面的可行性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2012 IEEE/MTT-S International Microwave Symposium Digest

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